Variable equalizer



Dec. 29, 1970 ENDO ETAL 3,551,854

VARIABLE EQUALIZERv Filed March 18, 1968 e Sheets-Sheet 1 INPUT PORT 1 FIGJ I H62 '1 rTWC-PORT NETWORK 1s K x j x v v KOUTPUT PORT 2 v-TWO- PORT 21 Z2 NETWORK 18 PORT . Two- PORT T NETWORK19 Two- PORT N TW 21 T FIG?) 1 cgrgaTgN T RESISTANCE v 2 H| ATTENUATOR 22 H3 f DELAY LINE23 \jYBRlD TRANSFORMER H BRIO TRANSFORMER I H2 S k H4 CONSTANT RESISTANCE ATTENUATOR 24 FIG.4'

CONSTANT RESISTANCE VARIABLE ATTE NUATOR 22 P \ICONSTA NT RESISTANCE |ATTENUATOR 24 Dec. 29, 1970 Filed March 18, 1968 6 Sheets-Sheet z U) 1: o U z 9 'T m- 4- Q A 2 3 I m Z O: i l I 1 2 4 FREQUENCY IN MCS F|G.6 x ATX ,REslsTANcE ATTENUATOR HYBRID TRANSFORMER HYBRID TRANSFORMER,

1 1 VOLTAGE H3 2 I DIVIDERS COUPLING sF. @QFSISTORS R Z1 I 01 22 sF Q R AMPLIFIER T B A H4 R 0 b T T REACTANCE HYBRID TRANS FILTERS TRANs.

l l I IMPEDANCE COMPENSATING CIRCUIT CN =5 KOICHI ENDO ETAL 3,551,854

VARIABLE EQUALIZER 6 Sheets-Sheet 5 Filed Margh 18, 1968 ms FREQUENCY LOG FREQUENCY FIG."

A .D 6 C R) H m d 7 MW 6 .F 2 K S T R N K 0 6 A R PO R V. PO W T w m OT E R WE T N Y H) 5 c b H 5 0 mm 4' W1 0 P 2 0T lm WE N F Dec. 29, 1970 RKOICHI ENDO EI'AL 3,551,854

VARIABLE EQUALIZER 6 Sheets-Sheet l -CONSTANT RESISTANCE Filed March 18, 1968 RIABLE ATTENUATOR 26 l DELAY LINE 25 HYBRID TRANSFORMER I CONSTANT RESISTANCE ATTENUATOR 27 HYBRID TRANSFORMER FREQUENCY IN MCS FIG.I3'

Dec. 29, 1970 YKOICH] ENDQ ETAL 3,551,854

VARIABLE EQUALI ZER 6 Sheets-Sheet 6 ,Filed March 18. 1968 WIDEBAND AMPLIFIER 31 NETWORK 32 United States Patent U.S. Cl. 333--28 7 Claims ABSTRACT OF THE DISCLOSURE A plurality of two-part networks are connected in a loop between an input port and an output port. The loop has a transfer coefficient which determines the variable frequency"characteristic of the variable equalizer and the transfer coefficient has a real coefficient which determines the proportional variation of' the magnitude of transmission of an electrical signal from the input to the output port.

DESCRIPTION OF THE INVENTIoN Our invention relates to a variable equalizer. The principal object of our invention is to provide a new and improved variable equalizer.

An object of ourinvention is to provide a variable equalizer which is of simple structure and which is economical in manufacture. 1

An object of our invention is to provide a variable equalizer which functions with efficiency, effectiveness and reliability, and with high precision.

In a'ccordance'with the present invention, a variable equalizer comprises an input port'and an' output port. A port is a pair of terminals. A plurality of two-port networks are connected in-a loop between the input and output ports. The loop has a'transfer coefiicient' which determines the'variable frequency characteristics of the variable equalizer and the transfer coefiicienthas a real coeificient which determines the proportional variation of the magnitude of transmissionof an electrical signal from the input port to the" output port.

In a first embodiment, a first of the networks has a transfer coefiicient x' and is connected between the input and output ports. A second of the networks hasa transfer coefficient Z1. A third of "the networks has a transfer coefficient z A fourth of the networks'has a transfer coefficient. ak. The second, third and fourth networks areconnected in series circuit with each other and the series circuit is connected in parallel with the first network. A 'fifth of the networks has a transfer coation of the magnitude of the transfer coeflicient of the efficicnt and is connected in parallel with the fourth network and z z =2x'y. The fourth network determines the frequency characteristic of thevariable equalizer.

In another embodiment, each of a plurality of the networks comprises a hybrid transformer. A separating network is connected between adajacent ones of the hybrid transformers in the loop. The separating network has a nearly constant resistance in a determined bandwidth.

In another embodiment, each of two of the networks comprises a hybrid transformer and each of a first, second and third of the networks is connected between the hybrid transformers. One of the hybrid transformers is connected to the input port and the other of the hybrid transformers is connected to the output port. One of the first, second and third networks has a transfer coefficient which determines the proportional variation "ice of the magnitude and phase of transmission of the electrical signal and the proportional variation is varied in accordance with the variation of one of gain and loss in transmission between the input and output ports.

In still another embodiment, a first of the networks has a transfer coefficient of the frequency characteristic. A second of the networks has an arbitrarily variable transfer coefficient. A third of the networks has a unilateral transfer coefficient and none of the plurality of networks comprises a hybrid transformer. The variable equalizer provides between the output and input ports a pure resistance wherein 2+ out and R and R is the input impedance, R is the output impedance, R is the power source impedance connected to said input port and R is the load impedance at said output port. The magnitude of transmission is variable to a constant specific frequency in accordance with varivariable equalizer.

In order that the present invention may be readily carried into effect, it will now be described with refererence to the accompanying drawings, wherein:

FIG. 1 is a block diagram of an embodiment of the variable equalizer of the present invention;

FIG. 2 is a signal flow diagram for the variable equalizer of FIG. 1;

FIG. 3 is a block diagram of an embodiment of the variable equalizer of the present invention which functions as a cosine equalizer;

FIG. 4 is a circuit diagram of the cosine equalizer of FIG. 3;

FIG. 5 is a graphical presentation of the transmission characteristic of the cosine equalizer of FIG. 3;

FIG. 6 is a block and circuit diagram of another embodiment of the variable equalizer of the present invention which functions as a composite variable equalizer;

FIG. 7 is a signal flow diagram for the composite variable equalizer of FIG. 6;

FIGS. 8a and 8b are graphical presentations of the transmission characteristic of the composite variable equalizer of FIG. 6;

FIG. 9 is a block diagram of another embodiment of the variable equalizer of the present invention;

FIGS. 10a and 10b are diagrams illustrating the principle of operation of hybrid transformers utilized in the variable equalizer of the present invention;

FIG. 11 is a signal flow diagram for the variable equalizer of FIG. 9;

FIG. 12 is a circuit diagram of the variable equalizer of FIG. 9;

FIG. 13 is a graphical presentation of the transmission characteristic of the variable equalizer of FIG. 12;

FIG. 14 is a block diagram of another embodiment of the variable equalizer of the present invention;

FIG. 15 is a circuit diagram of the variable equalizer of FIG. 14;

FIG. 16 is a circuit diagram of still another embodiment of the variable equalizer of the present invention; and

FIG. 17 is a graphical presentation of the frequency characteristic of the variable equalizer of FIG. 16.

In the figures, the same components are identified by I the same reference numerals.

In FIG. 1, the transfer coefficients of the respective branches 11, 12, 13, 14 and 15 of the variable equalizer are indicated by x, Z Z2, ak and y. Each of the five branches 11, 12, 13, 14 and 15 of the variable equalizer of FIG. 1 comprises a two-part network. The five branches are interconnected in a manner whereby the signal flow diagram of the transfer coefficient between the input port 1 and the output port 2 is that shown in FIG. 2. The twoport network 16 connected in the branch 11 and having a transfer coefficient x provides the main transmission path between the input port 1 and the output port 2 and the two-port networks 17, 18, 19 and 21 connected in the branches 12, 13, 14 and 15, respectively, and having transfer coefficients 2 z ak and y, respectively, provide the four auxiliary transmission paths from said input port to said output port.

In the aforedescribed condition, the transfer coefiicient S between the input port 1 and the output port 2 is defined as 1+ozk( %y) 82F; laky (1 The transfer coefiicient is influenced by the relationship z z =2xy The combination of Equations 1 and 2 produces a definition of the transfer coefiicient S as follows:

1 11] 1 aky 3 i The magnitude or extent of the transmission or transfer between the input port 1 and the output port 2 is then 1-aky 3 5 t a e) 1 and 1 If a variable having no relation to the frequency is selected as the transfer coefficient k or y and such variable is varied, the frequency characteristic of the variation of the magnitude or extent 0 of transmission between the input port 1 and the output port 2 is a and the extent of such variation becomes proportional to ky. As a result, the variable equalizer of FIG. 1 operates with extremely high precision. The two-port networks of the five branches of the variable equalizer of FIG. 1 may be either unilateral or bilateral. Any necessary amplifiers may be included in the circuit of FIG. 1.

The embodiment of FIGS. 3 and 4 functions as a cosine equalizer. In each of FIGS. 3 and 4, a hybrid transformer H comprises the two-port network of each of the branches Z1, Z x and y (FIG. 1). Thus, hybrid transformers H H H and H; are connected in the various branches of the circuit. Each of the hybrid transformers H has an attenuation characteristic of 3 db in each direction. The transfer coefiicient x of the two-terminal network H is thus equal to /2, the transfer coefiicient 2: of the network H is equal to /2 the transfer coefficient Z2 of the network H is /2 and the transfer coefiicient y of the network H4 is M1.

The frequency characteristic a is defined as wherein wherein f =2.4 megacycles per second or megahertz. A variable equalizer having a proportional constant kk, as shown in FIG. 5, is thus provided by the embodiment of FIGS. 3 and 4. In FIG. 5, the abscissa represents the frequency in megacycles per second and the ordinate represents the transmission loss in db. A constant resistance variable attenuator 22 has a transfer coefficient k and is connected in series circuit with a delay line 23 having a transfer coefiicient a, between the hybrid transformers H and H in FIG. 4. The delay line 23 has a plurality of inductors and capacitors. A constant resistance attenuator 24, having attenuation of 6 db, is connected between the hybrid transformers H and H in parallel with the series circuit 22, 23.

In another embodiment of the variable equalizer of the present invention, which functions as a composite variable equalizer, the magnitude or extent of operation and transmission 9 of electrical signals from the input port 1 to the output port 2, as shown in FIG. 6, is

M 0=0 i i wherein 9 is a predetermined magnitude or extent of transmission, a; is a function of the angular frequency (.0, which determines the form of attenuation and the phase characteristic, k is a coefficient having no relation to the frequency, so that :1 may be compressed or expanded without changing the form of the function by adjusting k and M is the number of independent variable characteristics or the number of types of 04 k The composite variable equalizer of FIG. 6 has loops which correspond to a plurailty of independent variable characteristics and utilizes separating networks. The variable characteristics are determined by the unilateral transfer coeflicients of the loops. The unilateral transfer coefficients are also coincident with the reverse direction in a passive circuit. The proportional variation of the magnitude or extent of transmission, involving the compression or expansion of e is provided by varying the real constant coefficient of the transfer coefficient, which real constant coefficient is the gain or loss in transmission. Furthermore, the characteristic indicated by Equation 5 may be provided in sum total by connecting the plurality of loops.

In FIG. 6, a plurality of hybrid transformers H H H and H similar to those utilized in the embodiment of FIGS. 3 and 4, are connected in the various branches, as in FIGS 3. and 4. The input signal is supplied to the composite variable equalizer of FIG. 6 via the input port 1 and the output signal is derived from the output port 2. A resistance attenuator ATx which has a transfer coefficient x is connected between the hybrid transformers H and H An amplifier is connected in the input of the hybrid transformer H A plurality of reactance filters SF SP SF are connected between the hybrid transformer H and the input to the amplifier a. An impedance compensating circuit CN is connected to the plurality of reactance filters SP to SF Each of a plurality of voltage dividers R to R is connected between the output of a corresponding one of the reactance filters SP to SF and the input of the amplifier Each of the voltage dividers R to R has a resistance value which varies the gain or loss of the shunts and which provides the port impedance of the separating network comprising the reactance filters SP to SF Each of a plurality of coupling resistors R to R is connected between a corresponding one of the voltage dividers *R to R and the input of the amplifier a.

In the composite variable equalizer of FIG. 6, the reactance filter SP to SF nearly satisfy the required conditions for operating as the constant resistance separating networks within the required frequency band. The reactance filters SF to SF are coupled to the amplifier t via the coupling resistors R to R which have resistance values R to R sufficiently larger than the port impedance R to R of the voltage dividers R to R so that it may be assumed that there is no interreaction between said reactance filters. Thus, the impedance, viewed from the point A in FIG. 6, to which the inputs of thereactance filters SP to SF are commonly connected in parallel, maybe made a constant or nearly constant resistance within the required frequency band. For, this reason, electrical signals are hardly reflctedat thepoint A. Q

, Thebasis foritheiexpression of the composite variable characteristics, wherein "the magnitude or extent of transmission from theinput port 1 to the output port 2 is Equation"5; is explained in the signal flow diagram of FIG."7.Tl1esignal flow diagram of'FIG. '7 discloses the transfer coefiicients 'of the branch routes. In FIG. 7, the maintrans'mi ssionroute from the input port 1 to the outputpo'rt 2 has transfer coefiicient at. The route from the input'portd to the point A hasa transfer coeffi'cient 2 "An auxiliaryro'ute fed back from the point B to the point A via "the b'ranchfroute from the hybrid transformer H to the hybrid transformer 'H hasa transfer coefli'cient y. A route from' the point A to the point B through a loop SF of the separating network has a'transfer'co- 'c offli i- Y The transfer coefficient S from the input port 1 to the output port 2 in the embodiment of FIG. 6 is exi ressed'as' izer circuit of FIG. 6. .provid es the signal shown in FIG. 7' and therefore functions asa composite variable equalizer. That is, in comprising the variable circuit in the composite variable equalizer of FIG. 6 a wave divider is utilized and the transfer coefficients of the loops of the wave divider are provided with the required frequencyamplitude characteristics, so that the real coefficient which is the gain or the loss in each loop, is varied and the variable characteristics may be adjusted proportionally.

The circuit arrangement of FIG. 6 functions as a composite variable equalizer when each of the hybrid transformers H H H and H has a loss of 3 db and the attenuator AT has a loss of 6 db. The transfer coefficients x, Z1, Z2 and y of FIG. 7 may then have the following magnitudes.

The composite variable equalizer of FIG. 6 then has the characteristics shown in FIGS. 8a and 811. FIG. 8a shows the characteristics of the reactance filters SF to SR... In FIG. 8a, the abscissa represents the logarithm of the frequency and the ordinate represents the loss in db. The broken line m is approximately 3 db. FIG. 8b illustrates the frequency bandwidth. of the variable equalizer. In FIG. 8b, the abscissa represents the logarithm of the frequency and the ordinate represents the fundamental loss in db. In FIG. 8b, 0 is approximately 12 db.

As shown in FIGS. 8a and 8b, the reactance filters SP to SF have a simple bandpass characteristic wherein the adjacent voltage attenuation characteristics may be overlapped with each other at a loss of approximately 3 db (FIG. 8a) and the variable characteristic is then that shown in FIG. 8b. In FIG. 8b, 0 indicates a reference line in a case in which there is no loop as aforedescribed, and the characteristic shown in the drawing may be provided by varying the resistance value of the variable coupling resistor R to R Signal reflection at the point A of FIG. 6 may be reduced by connecting the impedance compensating circuit ON in parallel with the reactance filters SF to SF as shown in FIG. 6. The impedance compensating circuit CN comprises inductance, capacitance and resistance.

Although the variable equalizers of FIGS. 3 and 6 each utilize four hybrid transformers, the embodiment of FIG. 9 utilizes only two hybrid transformers. In FIG. 9, the hybrid transformers H and H and three two-port networks 25, 26 and 27 having the transfer coefiicients a, y and ,8, respectively, are connected between the input port 1 and the output port 2.

FIGS. 10a and 10b illustrate theoperation of each of the hybrid transformers H and "H of the "variable equalizer of FIG. 9. Transmissionafright' angles such as, for example, from the lead a to the lead b in FIG. 10a, may be accomplished with a transfer coefiicient of 2. Transmission linearly from the lead a to the lead d in FIG. 10a cannot be accomplished because the transfer coefficient in' such case is zero. FIG. 'lOb is' a circuit diagram of a hybrid transformer. The two-port networks 25, 26 and 27, connected between the hybrid transformers H and H arematched at the leads 1;, d and c of said hybrid transformers. 1

The signal flow diagram of FIG.-11 indicatesthe transmission from the input port 1 to the output port 2 of FIG. 9. As shownin FIG. 11, the transfer coefficient S between the input port 1 and the output port 2 is defined as so that a combination of Equations 10 and 12 provides the following definition of the transfer coefiicient S The magnitude or extent of transmission 0 in a circuit having a transfer coefficient expressed by Equation 13 is i=1 When Equations 14 and 15 are combined, the magnitude or extent of transmission 0 is expressed as When the transfer coeflicient z of the hybrid in Equation 16 has a constant magnitude and 13 has a constant magnitude which satisfies Equation 12 and has no relation to the frequency, the magnitude or extent of transmission 0 varies in an amount A0 as follows:

Equation 17 clearly indicates that A0 is promotional to the transfer coefficient a. Thus, if the transfer cofiicient and if k has a magnitude or value which has no relation to the frequency, the variation in the magnitude of transmission A0 is defined as formers and adjusts the amplitude of the transmission to the gain or loss of said transmission line.

FIG. I2 is a circuit diagram of the embodiment of FIG. 9. FIG. 13 discloses the transmission characteristic of the variable equalizer of FIGS. 9 and 12. In FIG. 12, each of the hybrid transformers H and H; has a characteristic of 3 db. Thus, z=1/ /2l Th network 25 comprises a delay line having a delay of a which is approximately 0.5 microsecond. A constant resistance variable attenuator 26 having a transfer coefficient kk is connected in series circuit with the delay line 25 between the hybrid transformer H and the hybrid transformer H The network 27 comprises a constant resistance attenuator having an attenuation or characteristic 5 which is 8.3 db and is connected between the hybrid transformers H and H in parallel with the series circuit 25, 26.

In the variable equalizer of FIG. 12, the quantity or extent of transmission is In FIG. 13, the abscissa represents the frequency in megacycles per second or megahertz and the ordinate represents the magnitude or extent of transmission in db. In FIG. 13, the higher amplitude curve is derived at an attenuation kk of the constant resistance variable attenuator equal to A and the lower amplitude curve is provided at an attenuation kk equal to A;

Although four hybrid transformers are utilized in the embodiment of FIGS. 3 and 4 and in the embodiment of FIG. 6, and although two hybrid transformers are utilized in the embodiment of FIGS. 9 and 12, no hybrid transformer is utilized in the embodiment of FIG. 14. A variable equalizer without a hybrid transformer utilizes a circuit having a transfer coeflicient of the desired frequency characteristic, a circuit having a transfer coefficient which may be varied arbitrarily and a circuit with only unilateral transfer. The variable equalizer of such type provides a pure resistance R between the output port 2 and the input port 1 which is defined as wherein and R is the input impedance, R is the output impedance, R is the power source impedance connected to the input port 1 of the variable equalizer and R is the load impedance at the output port 2 of the variable equalizer. The magnitude or extent of transmission of the variable equalizer as a whole is adjusted to a constant specific frequency by variation of the magnitude of the transfer coefiicient.

In FIG. 14, the variable equalizer is connected between a pair of input ports 1, 1' and a pair of output ports 2, 2. A constant voltage source E is connected directly to the input port 1 and is connected through the power source impedance R to the input port 1. The load impedance R is connected between the output ports 2 and 2'. A unilateral circuit 29 transfers a signal only from a pair of ports 3, 3' to a pair of ports 4, 4. The unilateral circuit 29 has a short-circuit transfer admittance g(w) at an angular frequency w. The pure resistance represented by the resistor R is connected in a feedback shunt of th unilateral circuit 29 and permits the operation of the embodiment of F IG. l4 as desired.

-The operative transfer coefficient of the ,tWo-.port variable equalizernetworkof FIG. 14 is expressed as is combinedv withEquationZ-Z, theresultant; expression is r tel. The magnitude or extent of transmission is then 2R 1+"R';, "5 9 T 9" ET imo).

Equation 26 indicates that the magnitude or extent of transfer is proportional to g(w), except for a constant magnitude of in a range in which the higher order terms may be neglected. Thus, if g(w) is divided into a term having the desired frequency characteristic and a term having a magnitude or value which may be changed to an arbitrary constant, it is possible to adjust the magnitude or extent of transfer in proportion with the frequency characteristic of the term having the desired frequency characteristic by varying the term having a value which may be varied to an arbitrary constant and thereby provide variable equal- 'izer operation.

In FIG. 15, which is a circuit diagram of FIG. 14, the unilateral circuit 29 comprises a circuit 29A having a transfer coefficient k which may be arbitrarily adjusted. The unilateral circuit 29 also comprises a circuit 293 with a transfer coefficient ot(w) which has a determined frequency characteristic and which is relative to the angular frequency w. The unilateral circuit 29 further comprises a wideband amplifier 290 which has no frequency characteristic and which has a short-circuit transfer admittance g If impedance matching is provided between the circuits 29A and 29B and between the circuits 29B and 290, said circuits perform as the unilateral circuit 29 of FIG. 14 and the short-circuit transfer admittanc thereof is expressed as Accordingly, if Equations 23 and 24 are combined with Equation 26, the magnitude or extent of transmission or transfer is defined as It is thus possible to vary the magnitude or extent of 10 transmission or transfer 0 in proportion with ot(w) by varying k.

FIG. 16 discloses still another embodiment of the present invention which functions as a multivariable equalizer. The magnitude or extent of transmission or transfer of the embodiment of FIG. 16 is defined as M 0 0 00kl l wherein M is the number of independent characteristics a; which may be varied independently from each other or the number of parts of an independent characteriStiC d1.

FIG. 17 discloses the frequency characteristic of the magnitude or extent of transmission or transfer at the instants when the independent characteristics have a maximum amplitude. In FIG. 17, the abscissa represents the angular frequency w and the ordinate represents the magnitude of transmission 0. The curves presented are those ranging from i=1 through M.

A wideband amplifier 31 has an input impedance which is infinite, an output impedance R a short-circuit transfer admittance g and no frequency characteristic. A separating network 32 is connected between the input port 1 and the input of the amplifier 31, the output of said amplifier being connected to the output port 2. The separating network 32 has a nearly constant input resistance. The input impedance of the separating network 32 in R The separating network 32 comprises a plurality of partial filters 33 to 33 The terminating resistor 34 to 34 respectively, of each of the partial filters 33 to 33 of the separating network 32 has a resistance value of R The partial filters 33 to 33 of the separating network 32 are connected to the input of the amplifier 31 via a plurality of resistors 35 to 35 respectively, each having a resistance R.

Each of the resistors 35 to 35 has a high resistance value, so that the combined resistances R satisfy the condition R R and the resistors function as potentiometers for deriving voltages. When the voltage transfer coefiicients of the partial filters are (w) where i=1, 2, 3, 4, M -l, M and the position of the potentiometer is k where k is greater than zero but less than 1, the short-circuit transfer admittance between the input of the separating network 32 and the output of the wideband amplifier 31 is expressed as (90) t bz ki The magnitude or extent of operative transmission or transfer of the entire multivariable equalizer circuit of FIG. 16 is expressed as and the attenuation in operation or transmission loss is expressed as m )k N e i i( p 1 1 will occur to those skilled in the art without departing from the spirit and scope of the invention.

We claim:

1. A variable equalizer having a variable frequency characteristic, said equalizer comprising an input port;

an output port;

a plurality of two-port networks connected between said input and output ports, a first of said networks connected between said input and output ports having a transfer coefficient x, a second of said networks having a transfer coefficient Z1, a third of said networks having a transfer coefficient rack of which a represents the proportional variation of the magnitude of transmission of an electrical signal from the input port to the output port and k represents the magnitude of the characteristic of proportional variation, and a fourth of said networks having a transfer coefficient z said second, third and fourth networks being connected in series circuit with each other and said series circuit being connected in parallel with said first network, a fifth of said networks being connected in a feedback loop having a transfer coefficient y and being connected in parallel with said third network, and wherein z z =2xy.

2. A variable equalizer as claimed in claim 1, wherein said fourth network determines the frequency characteristic of said variable equalized.

3. A variable equalizer as claimed in claim 1, wherein each of said plurality of said networks comprises a hybrid transformer.

4. A variable equalizer as claimed in claim 1, wherein each of said plurality of said networks comprises a hybrid transformer and further comprising a separating network connected between adjacent ones of said hybrid transformers in said loop.

R is the input impedance, R is the output impedance, R is the power source impedance connected to said input impedance and R is the load impedance at said output port, the magnitude of transmission being variable to a constant specific frequency in accordance with variation in the magnitude of the transfer coefficient of said variable equalizer.

References Cited UNITED STATES PATENTS 1,947,621 2/1934 Schreiber 333-28X 2,907,838 10/1959 Ross 333-28UX 3,148,537 9/1964 Berwin et al. 333-28X 3,324,419 6/1967 Kuroda et al. 333-11X PAUL L. GENSLER, Primary Examiner U.S. C1. X.R. 333-41 

